DE1273214B - Method and device for the statistical quality control of products of mass production and for the regulation of mass production - Google Patents

Description

Method and device for statistical quality control of Products of mass production and for the regulation of mass production The present The invention relates to a method and a device for statistical quality control of products of mass production and for the regulation of mass production, in which each a predetermined number of copies of the manufactured products Run through measuring device and the values determined by this a statistical Evaluation device are supplied, which generates control signals.

The application of statistical methods to regulate manufacturing processes is important wherever the variable to be regulated, the so-called quality mark, z. B. size, weight, chemical composition, etc., a statistical character has, d. H. is afflicted with random deviations and by one of the Gaussian Curve-like distribution function can be represented.

A device has become known in the cigarette industry, with which a continuous registration of the mean values of quality marks in five Classes is made, two of which are reject classes and outside of the Tolerance range, while three classes are within the tolerance range. Of these three classes, the true-to-size pieces are counted in a class while in the other two classes the pieces with oversize and undersize are counted, but which in their deviations from the nominal value do not yet deviate so far that sorting out is necessary. Here the registration is made to a To enable evaluation by the operator. The operator knows that the cigarette machine works particularly well when that corresponds to the nominal value Counter has the highest possible values, the counters in the inspection classes if possible do not show any numbers and the counters of oversize and undersize accuracy Display numbers that are as equal as possible. An evaluation of only made by the operator.

Now the application of methods of mathematical statistics is in well known in manufacturing and has already led to notable successes and manufacturing cost reductions. The statistical methods of quality control make it possible to achieve an almost any accuracy of the manufacturing process using statistical Control factors that determine the location and spread of the relevant quality mark of the characterize statistical distribution. These rule factors (also selection or statistical parameters) are and will be subject to random fluctuations usually by calculating from the results on a selection of measurements obtained using mathematical statistical methods. By comparing each statistical characteristic value with its limit value determined by the control plan it can be determined whether its deviation, i.e. H. the instant difference is statistically significant or not. Is the difference in statistical Significant respect, care must be taken that the quality mark to be recorded reaches the prescribed value again. This mathematical statistical procedure however, has the disadvantage that the calculation is complicated and time consuming and requires a trained academic staff.

Automatic devices for regulating a quality label are already to carry out such a regulation according to a statistical method has been developed by means of a computing device. The devices known so far however, use characteristic values as control factors that are continuously used in statistics be: the arithmetic mean X, the range R (Range) or similar common statistical parameters. These parameters are first set in the facility calculated from the specific number of measurements and can only then compared to the prescribed limits. The comparison result is used by the statistical engine to generate pulses that the operator transmits appropriate signals so that they can complete the manufacturing process can adjust accordingly. In the case of an automatic control of the manufacturing process are the same pulses in a servo device to carry out the required Setting on the machine used.

If z. B. the mean value X as the effective characteristic value is used, a selected number of measurements, the so-called "readout" or "Selection number" n, can be made, the apparatus first taking the measurement results added together and then divided by the number n. Of course you need this Process a rather complicated mathematical machine. The use of the other The characteristic values used in statistics have at least these or even more complex ones Facilities result.

By an earlier patent are a method and an apparatus for Proposed regulation of manufacturing processes according to measured values taken at random have been, in which a number before n consecutive, in the production flow in time Arbitrarily distributed individual values are taken and combined into a sample is, in such a way that, after formation and testing, one each of rc individual values is summarized Sample to form a further sample, the first single value is deleted and a new individual value is added for this. An examination of the second sample consisting of (n - 1) old and a new single value with regard to Iterations performed. The procedure is used to form a third, fourth Sample etc. continued in the manner described; it can thus be used as a Iteration control system with continuous sampling. This system is constantly bringing new values, but it can change the speed of a machine but only grasp slowly because not a series of consecutive workpieces is subjected to an examination. This is the selectivity of this device limited. The deviations from the standard are relatively wide.

The present invention overcomes the aforementioned disadvantage. The inventive Method considerably simplifies the application of the known statistical procedures and occasionally leads to other, unusual statistical parameters that lead to Solution of the problem posed are more advantageous.

The inventive method consists in that the measuring range of Measuring device by setting predetermined ones lying within the tolerances Limits are divided into separate areas that in each area of the measuring device one of the number of copies passing through this area corresponding number of counting pulses is generated that these counting pulses correspond to the statistical Evaluation device are supplied, that these are added in the device and that sums and / or differences of area pulse numbers formed and with set control limit values are compared and that this comparison is used to control the production will.

It is useful that the measuring range of the measuring device by Setting of two predetermined limits is divided into three measuring ranges. However, more predetermined limits can also be selected.

The regulation can advantageously be based on a procedure that in the statistical evaluation device is the difference between the two external area pulse numbers is formed or in the case of the statistical evaluation device the sum of double Number of a measuring range and the middle measuring range is formed or at that in the statistical evaluation device is the sum of the counting pulses in the two external ones Measuring ranges is formed.

It can also be useful that in the statistical evaluation device at the same time the sums and differences of the counting pulses of the external measuring ranges are formed or that in the device the sum of the pulses of the middle measuring range at the same time and the double sum of an external measuring range is formed.

This method of statistical quality control is carried out with a device in which a measuring device is provided, which accordingly the measurement of undersized, dimensionally stable or oversized products supplies corresponding impulses to a statistical evaluation device, and which ones according to the invention characterized in that the statistical evaluation device according to the Principle of the group method works and on the basis of one or more statistical Evaluates characteristic values.

This device is advantageously designed so that for the statistical Evaluation device different summers are provided, of which the first the Number of measurements, the second the number of times exceeding the upper control limit Measured values, the third the number of those which fall below the lower control limit Measured values, the fourth the sum of the values of the second and the third and the fifth the difference between the values of the second and the third is determined.

The principle of the statistical group method is based on the fact that one Selection of n measurements according to the measurement results using certain limit values of the tracked quality mark is divided into several groups, with the number of the products or measurements in each group to calculate the corresponding statistical characteristic value (parameter) is used. So z. B. be in the case of two statistically prescribed control limits the following three groups (categories) obtained from products or measurements. This three group method is shown in the following Explanation deals exclusively with: a) the so-called "good" group of measurements, their measured values within that limited by the two control limits mentioned above Control area, the number of which is denoted by g, b) the "oversized" Group of measurements whose values are above the upper control limit, whose Number is denoted by z +, c) the "undersized" group of measurements whose Values are below the lower control limit and their number is denoted by z _ will. In special applications, preferably by determination of more than two control limits, more than three groups can be used.

From the number of measurements in the individual groups, over conclusions can be drawn about the nature of the statistical distribution. If z. B. the mean of the distribution, the distribution curve, in the direction of the larger Values is shifted, the number z + increases, and the number z_ decreases, whereas the flattening of the distribution curve to a simultaneous one as a result of the increased scatter Increasing the two numbers z + and z_ and leads to a decrease in the number g. The use of statistical parameters is particularly advantageous in this invention (Characteristic values), which are determined by the sum S = z, -h z _ and the difference r = z ,. - z _ given are. But other suitable statistical parameters can also be set by simple Arithmetic operations can be derived from the numbers z,, z_ and g.

Embodiments of the device according to the invention are shown in Drawings illustrate wherein the same reference numerals are used to denote of corresponding components having the same mode of action are used will. It shows F i g. 1 is a block diagram of one of the known manual statistical Control devices, F i g. 1 a is a diagram in right-angled coordinates, which the normal distribution of measurements and their division into the three groups mentioned shows F i g. 2 a block diagram of a simple statistical evaluation device according to the principle of the group method, F i g. 3 a scheme of an automatic statistical Evaluation device, F i g. 4 and 5 schematic representations of a statistical Device for regulating dimensions, in which a known measuring device is used as the measuring element is used, the three measuring ranges (spans) by sending out different Signals. In the embodiment according to FIG. 4 will just be a stock change of the apex of the distribution curve, while in the one shown in FIG. 5 shown Example both a change in the position of the vertex and the spread of the distribution is indicated, F i g. 6 shows a block diagram to explain a statistical quality indicator control device for continuous measurements, FIG. Figure 7 is a block diagram showing greater detail a quality label control device for continuous measurements.

F i g. 1 schematically illustrates a statistical evaluation device according to the prior art. A machine PM, which produces products or components characterized by the quality mark to be recorded, is connected to a measuring device G, 4. This conveys information about the quality mark to be recorded in a statistical evaluation device SE provided with a signal device SM. The drawn three-channel signaling device SM has z. B. as a signal transmitter on different colored bulbs. A signal transmitter SB conveys information about the accuracy. Signal transmitters S + B and SB give instructions on how the machine PM, e.g. B. a centerless grinding machine, corrected or readjusted. So z. B. the response of the signal generator SB that the value of the quality label, that is the dimension to be detected, must be increased, and the response of the signal transmitter S + B indicates that a reduction in the quality label size is required. The actual regulation, ie the setting of the machine PAi, can then carry out a learned force in accordance with the signals.

However, the use of the group method of mathematical statistics has significant advantages. The simplest application of this method is based essentially on the fact that the change in position of the apex of the distribution function of the quality label is determined by means of the difference r = z + -z- (1) and the change in scatter is determined by means of the sum s = z + + Z- (2) .

This principle is applied to the distribution DB of the quality label in FIG. 1 a illustrates. In this diagram, the value of the quality label is plotted as the abscissa and the relative frequency is plotted as the ordinate. Since the dimensions of no test object should be outside the tolerance range, the entire distribution curve DF lies between the lower tolerance limit TL and the upper tolerance limit Tu. The lower control limit CL and the upper control limit Cu divide the area below the curve DF into three parts. The control limits CL and Cu are determined by a control plan drawn up according to the work process. The statistical control plan specifies the selection number n and the mean square deviation of the quality label. The mean square deviation is calculated from the analysis of the accuracy of the manufacturing process and used to determine the control limit range mentioned. The statistical control plan also specifies the so-called statistical control limits RS, R, U, R, L, which determine the permissible deviation of the statistical characteristic values S and r. The statistical control limit for the sum S is denoted by RS. The statistical characteristic value S indicates the accuracy of the production, since an increased spread of the curve DF means an increased inaccuracy of the machining process. The sum S is compared in the statistical evaluation device SE with its control limit RS. If the sum S is greater than RS, an electrical voltage is applied to the signal generator SB, and the machine PM must be shut down and the manufacturing accuracy must be increased.

For the statistical characteristic value r- according to formula (1), two statistical Control limits are set. The lower control limit R, L in this case has one negative quantity, and if the characteristic value r is smaller, d. H. a bigger negative Has a value, the signal transmitter SB is actuated. On the other hand, the signal generator SB only actuated when the characteristic value r is greater than the upper statistical control limit R, u, each of which is a positive number in this case.

F i g. 2 schematically shows a simple embodiment of a statistical evaluation device according to the present invention which works according to the group method. The device essentially contains the following components: component C ", which counts all measurements and signals the end of the selection of the n parts; component C, which counts all measurements (z,) lying above the upper control limit Cu; component Cz-, which counts all measurements (z-) lying below the lower control limit CL ; unit CS, a simple summing device which determines the sum S according to equation (2); unit C "which determines the difference r according to equation (1).

The two units CS and C are equipped with a signaling device, not shown connected, in which the comparison of the parameters obtained? -and S with the prescribed statistical control limits takes place and what a significant deviation of a which shows the characteristic values S or r. So z. B. exceeding the permissible RS value shows a significant change in the spread. It is then necessary that Increase the accuracy of the manufacturing process. Exceeding the permissible Values R, .U (or R, L) in the »plus« or

Minus «direction means a significant change in the position of the apex of the distribution function, ie a significant change in the setting of the corresponding machine in the direction of larger or smaller values of the quality label. The summation and difference formation in the units CS and C can, for. B. be carried out by means of electrical counters. As units C ", CZ +, Cz-, CS and C, the most suitable direct current fed electromagnetic stepping switches (telephone dialers) and telephone relays. The first unit C" determines the number of individual parts measured, the second unit C adds up the number above upper control limit Cu, the third unit C, - sums the measured values below the lower control limit CL , the fourth unit CS sums the values of the second and third units Cz .. and Cz-, and the fifth unit C, forms the difference the values indicated by the units C, + and C, -.

The deletion of the display values is done by means of specially switched contacts of the step switches, breakers and telephone relays. The number n (selection number) of the measurements to be processed as well as the limit values for CL, CU, CS, CL and Cu can be set with this device by means of setting switches (step switches) on the front panel.

In, F i g. 3 shows the scheme of an automatic statistical evaluation device. The machine PM, e.g. B. a roll stand for sheet metal production, has as a measuring device GA an electrical device serving storage unit for the appropriate statistical evaluation device SE with a memory unit serving as a memory unit for the appropriate statistical parameters, z. B. r and S, works with correction devices CD, and CD- together, which automatically regulate the machine PM with the help of a servo device in such a way that the device CD, in the given case one. Magnification and the device CD- a reduction of the measured variable to be monitored, in this example the thickness of the rolled sheet.

The signal transmitter SM of FIG. 3 is, although not essential, CD in addition to the devices. and CD- provided and connected to the unit SE. It is advantageous to provide a registration device RA. This device can not only convey information about the course of the measured variable, but also an overview of the operation of the control device. The deletion of the display after each adjustment of the machine is necessary if the selection n of the measurements is made continuously, because this prevents the measurements carried out before the intervention in the machine from influencing the control after the intervention.

To determine the difference r, this requires in FIG. 2 shown Device three building units: a summator Cz +, which for a given number from measurements n determines the value z +, a second summator C_ _ for the value z- and finally a third device Cr, which determines the difference r = z + - z-.

If a known measuring device is used for the measurement, which the quality mark is signaled in such a way that a white signal light lights up when the DUT is within the tolerance limits that if the value falls below the lower limit Tolerance limit or, if there is no test item in the measuring device, a red signal lamp lights up, and that for dimensions above the upper tolerance limit a green The signal light shines or signals that can be distinguished in some other way are given, this simplifies the statistical evaluation device considerably, and it is then sufficient a single summator. If now this known device as a measuring device for statistical Control is used, its limits are set to "control limits" instead of Tolerance limits set. The control limits are z. B. the value of the middle quadratic deviation above and below the arithmetic mean stipulated, d. That is, the control area closes a third of the tolerance range a. Hence, the terms "undersized" and "excessively" refer to the control limits given by statistical considerations and not, as with known ones Measuring apparatus common to the tolerance limits.

The following three cases can occur if the test object passes through the test section occur: a) The test item is below the lower tolerance limit (insufficient); red signal light appears; b) the test item is within the tolerance range (true to size); the red-white-red signals light up one after the other; c) is the examinee above the upper tolerance limit (excessive); the signals light up one after the other Red-white-green-white-red.

According to the invention, instead of the difference r (equation 1), either the sum of the red and green light pulses (r1 = R -I- G), which were previously mentioned in the description of the electrical measuring device, or, even more simply, the sum of the white light pulses is used for display purposes Light pulses (p. = W), where R is the number of red light pulses corresponding to the selection number h, G is the number of green light pulses corresponding to the selection number n, W is the number of white light pulses corresponding to the selection number n. Because the number of oversized test pieces above the upper control limit Cu is directly indicated by the expression z ,. = G (3) given.

The number of dimensionally stable (good) test pieces g is given by the relationship g = W - 2 G (4) , and the number of test pieces below the lower control limit CL is given by the equation z- = n + 1-R (5) , where the number of test objects measured, the so-called selection number, is evidently given by the expression n = zt + g + z- (6).

The relationship r = z, -z- = R + G- (n + 1) = r1 - (n -t- 1) follows from equations (1), (3) and (5). (7) Furthermore, the expression r = z + -z- = Wh = r2-n (8) can be derived from equations (1), (3), (4), (5) and (6).

From equations (7) and (8) it can be seen that due to the constancy of the value n instead of the characteristic number r, the difference according to equation (1), ie either the index r1 = R -, '- G or the index r ., = W can be used.

The device of FIG. 1 operating according to the invention. 4 contains the following components: an electrical measuring device 1 of known design with a switching armature 11 and the contacts 12 and 13, a two-pole changeover switch 2, a telephone dialer 3 with an electromagnet 31, an auxiliary contact 32, a contact set 33 divided into sections A, B and C. and a contact set 34 (all contacts except the first connected together), a polarized relay with a contact 41, a relay 5 with contacts 51, 52, 53, 54, 55, 56, 57, a resistor 6 and signal lamps 7, 8, 9.

The device can work in two ways: In position I of the switch 2, the device according to the invention works as a counter of the "white" pulses W, that is, the device counts how often the armature 11 is in the position between the contacts 12 and 13 of the passage of the n test items. After the number n of test objects has passed under the sensor of the encoder 1, the signal lamps 7, 8, 9 indicate whether the code r, = W, which is equivalent to the difference r, is above a previously determined upper or below a lower statistical one Control limit value is or whether this characteristic value W lies in the range between the two control limits and therefore no readjustment of the machine is necessary.

When the switch 2 is switched to position II, first the information collected in layer 1 is deleted and the device operates as a usual signal transmitter for the electrical measuring device 1, d. i.e. it will be instantaneous The position of the armature 11 in relation to the contacts 12 and 13 is indicated. The signal lamps 7 (green), 8 (red) and 9 (white) indicate whether the device under test is just passing through Oversize or whether the test item is undersized or whether the test item is dimensionally accurate.

The position 11 of the switch 2 is also used to set the device to the control limits. The control limits C1 and Cu, as mentioned above, must namely, according to the statistical control plan, be set far narrower than the tolerance limits TL and TU of the conventional measuring device (see FIG. 1 a).

In position 1 of the switch it is signaled where the arm of the contact selector 33 is located. The signal lamps 7, 8, 9 indicate which section A, B or C of the row of contacts 33 the selector arm touches. So shows z. B. the lighting of the green lamp 7 that a significant change in the position of the mean value of the quality mark in question has occurred in the direction of the excess, the lighting of the red lamp 8, the tendency to the formation of the undersize is indicated, and the white light of the Lamp 9 means that the setting of the manufacturing process is OK. The relevant information is only signaled after the whole number n has been run through.

The device of FIG. 4 works as follows: The two-pole switch 2 is switched to position 1. The direct voltage from a battery 15 is thus applied to the relay 5 via one pole of the changeover switch, and this direct voltage is also fed to the contact 41 of the relay 4. The relay 5 is energized, whereby the changeover contacts 51, 52, 53, 55 and 56 are actuated, the normally open contact 57 is closed and the normally closed contact 54 is opened. The armature of the changeover contact 51 connects the green signal lamp 7 with the segment A of the contact set 33. The armature of the changeover contact 52 connects the white signal lamp 9 with the segment B of the contact set 33, and the armature of the changeover contact 53 connects the red signal lamp 8 with the segment C of the contact set 33. The normally open contact 57 connects the contacts 12 and 13 of the electrical measuring device 1. The normally closed contact 54 switches off the contact 41 from the direct current low voltage source. The armature of the changeover contact 55 connects the armature 11 of the measuring device 1 via the auxiliary contact 32, which is still open for the time being, to a now dead contact of the changeover switch 2. The armature of the contact 56 connects the electromagnet 31 of the selector 3 via the normally closed contact 41 with the voltage from the source 15. The source 17 of the low voltage is connected to the contact armature 11 of the measuring device via the second pole of the switch 2. As long as there is no test item in measuring device 1, the following circuit is closed: DC voltage from source 17 - armature 11 - contact 13 - contact 57 of relay 5 - polarized relay 4 - ground. In the rest position, the armature 11 of the measuring device is in contact with the contact 13, since the spring keeps the sensor permanently in the lower limit position. This opens the contact 41 of the relay 4, and the device is now ready to receive the statistical control indicators of n items.

When inserting a test specimen with undersize, the anchor 11 is always at contact 13 and no change occurs. In the case of a dimensionally stable, i.e. H. The armature 11 lifts from a test object lying within the control limits Contact 13 from. As a result, the relay 4 is de-energized, the normally closed contact 41 closes, and the voltage from the battery 15 reaches the electromagnet via the contact 56 31, which is excited and advances the switch arm of the selector 3 by one step. When the test item leaves the measuring device, the armature 11 rests on the contact again 13 on, the relay 4 responds, opens the contact 41 and thus switches the electromagnet 31 from. The selector 3 has carried out a switching step and the switching arm is located is still in segment C of the contact set 33, which voltage from the battery 17 is fed. The red signal lamp is connected to segment C via contact 53, a current limiting resistor 6 being switched into its circuit.

When inserting an oversized specimen, the armature 11 first lifts off the contact 13 , remains for a certain time between the contacts 13 and 12 and then finally rests against the contact 12. In. the time in which the armature 11 is between the contacts, the selector 3 also takes a step. When the test specimen is removed, the armature 11 again comes between the contacts 13 and 12, and the selector takes a further step. When passing through a test object with oversize, the selector carries out two steps, because the armature 11 is located twice in the intermediate position between the contacts 12 and 13. If the switch 2 were in position II, it would light up red-white-green-white-red, but in position I of switch 2, device 1 only sends the two pulses corresponding to the white light.

After passing through n test items, the voter carries out a certain number W of steps. If the number of steps is less than (n - c), where c means the permissible deviation of the statistical code r2, which is assumed to be c = R, .u = -R, c for the sake of simplicity, the red signal lamp 8 lights up, because that Segment C of the contact set 33 contains the contacts with the serial numbers 1 to (n - c -1). If the number of steps is in the range n ± c, the white signal lamp 9 lights up, because segment B of the contact set 33 contains the contacts with the serial numbers (n - c) to (n - a c). In the case of a greater number of steps than (n + c) the green signal lamp 7 lights up. The red signal lamp 8 means a statistically important shift of the mean value of the distribution to lower values, the green lamp 7 to higher values, and the white lamp 9 announces indicates that no significant change has occurred. This can be explained as follows: With the test number n, the number of white pulses W can be in the range from zero to 2n. When W is n, it means that the distribution is symmetrical about the arithmetic mean. The permissible deviation c was determined by statistical calculations, ie by how many pulses the mean number W = n can be exceeded or undercut. In other words, the device should still approve the distribution, ie the signal lamp 9 should light up white when the number W is in the range (n-c) and (n-f-c). For example, with n = 10 and c = 3, the number of white pulses W after the selection of ten pieces has been completed may be between seven and thirteen.

The segment C of the contact set 33 must then have (n - c -1) contacts to have. These contacts can be designated with the serial numbers 1 to (n - c - 1) be, d. H. in the example given, the first to sixth contact. The segment B has twenty contacts with serial numbers (n - c) to (n -I- c), after which Example above six contacts, which are the seventh to thirteenth contact are designated. Row A begins with the contact (n -t- c -I- 1), i.e. H. with the fourteenth contact.

From this it follows that although theoretically 2 n contacts in the segments A, B, C are indicated as the sum of all contacts in the range 0 to 2 n, it is sufficient for the function if the segment A is provided with only one contact, namely the green lamp already lights up when the contact arm reaches the contact (n + c -I- 1), and even if the arm were to carry out further steps, this could not change anything in the signaling.

After completion of the measurement of the full selection number n, the information stored in the selector 3 can be deleted as follows: The switch 2 is switched to position 11. The voltage from the battery 15 then reaches the contact set 34 of the selector 3 from the first pole of the switch 2. If the voter is not in his basic position, he will get to the contact record 34 belonging switching arm the voltage once to the relay 5, which is energized, and also to the contact 41. The voltage arrives at the second pole of the switch 2 from the battery 17 to one pole of the auxiliary contact 32. Because by switching the Switch 2 in position II disconnects the low voltage from the battery 17 from the armature 11 is, the relay 4 drops out, and the electromagnet 31 of the selector 3 is via the Contact 56 excited. Auxiliary contact 32 then closes. Via contact 55 reaches the armature 11 voltage, and the relay 4 responds, whereby the current of the voter magnet 31 is interrupted.

This proposal repeats itself automatically until the voter runs into its original position, the switching arm belonging to the contact set 34 leaves the row of interconnected contacts, so that both the relay 5 as well as the contact 41 are without voltage. This is the device for signaling prepares individual measurements and thus provides the services of the signaling organ of a electrical measuring device. The armature 11 is connected to the low voltage via the changeover contact 55 laid out of the battery 17, the contact 57 opens, and the contact 41 is The voltage from the battery 18 is supplied via the normally closed contact 54.

The green signal lamp 7 is via the changeover contact 51 with the contact 12 of the measuring device, the red signal lamp 8 is above the Switch contact 53 connected to contact 13 and the white signal lamp 9 via the changeover contacts 52 and 56 connected to contact 41.

If now in this position 1I of the switch 2, the armature makes contact 13 touches, the electric current comes from the source 1.7 via the contact 53 to the two lamps 8 and 7. The necessary electrical potential is applied to lamp 8 generated. Since the lamp 7 is connected to the relay 4 through the contact 51, there is insufficient potential for this lamp 7 to light up. Simultaneously the contact 41. is opened by the relay 4, so that the lamp 9 is also de-energized is. Therefore, in this case only the red light B.

If the armature 11 touches the contact 12, the contact 51 is the green lamp 7 fed with electrical voltage, which via the resistor 6 on Ground is switched. At the same time, however, contact 12 is also via the relay 4 connected to ground, so that the contact 41 opens and the lamp 9 without power is. So it only signals the green lamp 7.

When the anchor is in the intermediate position and none of the Contacts 12 or 13 touched, the relay 4 remains de-energized, and through the closed Contact 41, only the white lamp 9 is brought to give a signal.

So it works in the position 1I of the switch 2, after the deletion of the information stored in the selector 3 has been carried out, the device exactly like the above-mentioned measuring and signaling device, so that in a simple manner the control limit values CL and CU of the quality mark, the required for statistical control according to the present invention can be set.

The in Fig. The device illustrated in FIG. 4 correctly regulates the quality of production, provided that it is a matter of a change in the vertex position X of the distribution DF of the quality mark in question (FIG. 1 a). In series production there are z. B. the device shows the change in the setting of the manufacturing process, but in no way shows the spread of the distribution of the quality mark, ie the degree of accuracy of the manufacturing. This information is replaced by another key figure, e.g. B. given by the sum S = 2 + + z-, (2).

According to the invention, instead of the sum S according to equation (2) is displayed the change in dispersion is the difference between the number of pulses and the number of Flashing the white light minus the double value of the flashing green Light used. In a simplified version, the difference is the number of the pulses corresponding to the red and green lights are used for the same display.

Because from the above equations Z, G, g = W-2G, (4) z_ = n + lR, (5) n = z ,. -I- g + z- (6) the following relationship can be derived: S = z ++ z- = ng = n + 2G-W = n-S2. (9) Alternatively, one can derive the following relationship: S = z + + z_ = G + n + 1-R = n + 1 + GR = n + 1-Sl. (10) In view of the fact that the number n is a constant, the number of signals S2 = W - 2 G according to equation (9) or, alternatively, the number of signals S1 = R - G according to equation ( 10) can be used.

This exemplary embodiment is illustrated with reference to FIGS. 5 of the drawings will be explained in which an example of a device working on this principle is shown schematically.

The device in question is according to the statistical control device F i g. 4 is similar, except that there are provisions for displaying the change in position the pursued quality mark z. B. a measure taken by means of light bulbs 7, 8, 9, to display the changes in the spread of the same quality mark z. B. by means of a control lamp 50 to perform.

The device according to FIG. 5 differs from the device according to FIG. 4 only by the following features: The relay 4 has two excitation windings, whereby the use of the contact 57 is omitted. The reduction resistor 6 is connected between the contacts 56 and 55, so that the interruption contact 54 is omitted. The relay 5 also has two excitation windings. In comparison to the one shown in FIG. 4 includes the embodiment shown in FIG. 5, the following additional units are required to form the sum S2 according to equation (9): a) a polarized relay 10 with a changeover contact 101, b) a telephone dialer 20 with an electromagnet 201, changeover contact 202, contact row 203 and continuous row 204, c) a reduction resistor 30, d) a relay 40 with a break contact 401, e) a signal lamp 50 to indicate a significantly increased spread, f) a telephone dialer 3 according to the original design, extended by a number of further signal rows 35 to 38 , which are designated in the drawing with ordinal numbers 1, 2 ... j.

The operation of the in F i g. The device shown in FIG. 5 runs as follows: The number of components of the readout n whose quality markings are above the upper control limit is registered on the selector 20, which is rotated by one step in each case when the armature 11 touches the contact 12. This is done by means of the relay 10, which introduces current through the switching contact 101 into the electromagnet 201 of the telephone dialer. The contacts of the signal series 203 are connected to the signal series 35 to 38 of the selector 3 in such a way that the contact of the series 203 labeled with a certain ordinal number (1 to j) is connected to that signal series of the selector 3 which has the same ordinal number is designated. The first contact of the signal series 203 is connected to the contact arm of the signal series 35, the second contact of the same series 203 is connected to the contact arm of the signal series 36, and so on, until the j-th contact of the series 203 is connected to the contact arm of the j-th signal series 38 of the Selector 3 is switched. Each of the signal series 35 to 38 of the selector 3 has a certain number of first contacts connected in series. The number K of interconnected contacts of the a-th row depends both on the size of the selection n and on the size of the statistical control limit RS for the sum S.

The number K can be determined according to the following simple equation: K = n-RS + 2a-2, (11) where K is the number of interconnected contacts of the a-th Row of selector 3, n the readout range, RS the value of the control limit for the total S = z ,. + z_ and a means the ordinal number of the series.

On the contact arm of the signal series 203 of the selector 20 is a through the resistor 30 to z. B. 6 volts reduced voltage from z. B. 40 volts from the Source 15 led. Depending on the location of the contact arms of the selector 20 and 3, the After the selection n has been completed, the incandescent lamp 50 is either lit up or not. The incandescent lamp 50 is namely grounded with one pole, while with the other Pole to all K contacts interconnected according to the instructions above the rows 35 to 38 of the voter 3 is connected.

If after completing the selection n the light bulb 50 signals, this means that the number of pulses corresponding to the white and green light according to equation (9) was not sufficient.

When switch 2 is switched to position II, it reverses the selector 20 in a known manner in its basic position by means of the relay 40 with the contact 401 and by means of the continuous row 204 and the contact 201 back. The voter 3 returns to its basic position, as in the previous example with respect to FIG. 4 has been set out.

When using the device according to FIG. 5, e.g. B. in series production of constituents, a number of n constituents is under the measuring pin of the measuring device 1 pushed. After inserting the last piece it must be determined whether on the switchboard of the device a light for signaling an increased Dispersion, d. H. the lamp 50 lights up. In the event that the light does not shine, has the spread does not increase significantly. The lighting up of the light for the indication the spread means that the spread has increased significantly and that the adjustment accuracy of the creation process must be changed.

In Fig. 2 shows a statistical evaluation unit SE , in which the numbers z, and z_ are counted by means of the counters CZ + and C, _ and from these into the summator C,. and C5 the statistical key figures r = z + -z_, (1) S = z + + z_ (2) are formed. The following two equations can be derived from the relationship n = z ++ g + z_ (6) : r = 2z ++ gn (11) [from equations (1) and (6)], S = ng (12) [from the equations (2) and (6)].

Since the selection number n is to be regarded as a constant number, the following two characteristic values can be used instead of the characteristic number given by the formulas (1) and (2): r '= 2z, + g, (11') S '= g . (12 ') The statistical control limits must then of course also be changed accordingly. If the code number S ' (instead of the number S) is used, the display of the impermissible change in the spread must be carried out every time the number S' is smaller than the statistical control limit RS i.

The statistical evaluation by means of the index r 'and S' according to the Equations (11 ') and (x2') is particularly advantageous when the continuous display and evaluation of the so-called "movable" statistical key figures will.

The ongoing process for statistical quality control on the basis of of moving indicators is characterized in that the statistical control factors or key figures are continuously evaluated from the last n measurements. this means that when regulating a series of products, the last measured Product forms the last link in selection n. The advantage of this procedure can be seen in the fact that the operator's attention is instantaneous or directed to any manufacturing error within a very short time which is why it is not necessary to wait for the measurement to complete Selection number n is completed.

In contrast, the normal is interrupted or intermittent Process the selection is carried out item by item, and the result for each item emerges after the whole lot has been examined. Only then can the next one Item, that is the selection number n, must be examined and the control must wait until the investigation of this item is finished.

F i g. 6 shows a schematic representation of the statistical evaluation unit for the uninterrupted evaluation of statistical key figures. The evaluation device ST contains several units: a distribution device D, a storage element M, consisting of storage units, e.g. B. relay units, or a magnetic tape. The like., An evaluation unit E, an erasing unit F and a switch S which is set to a predetermined constant position. The in F i g. The device shown schematically in FIG. 6 operates as follows: The pulses corresponding to the value of the quality label to be measured, emitted by the measuring unit GA, are conveyed through the distributor D to the storage units M, where they are stored and retained in the order in which they were registered. The selected value of the selection number n is set in the switch unit S. The evaluation unit E calculates the relevant statistical characteristic values from the values contained in the memory unit M and transmits a corresponding electrical voltage to the signaling device SM when the value of the statistical characteristic value exceeds the predetermined statistical control limits, as already explained. In contrast to the evaluation units described so far, the unit E can also work during the time when the number of measurements has not yet reached the number n. During this time interval, the currently evaluated statistical characteristic values are compared with the predetermined statistical control limits, which correspond to the number of measurements made up to this moment.

After (n -h 1) measurements, the information from the first measurement must be deleted. This is done by means of the erasing unit F, which erases the first measured value. Each further measurement causes the deletion of the further - in each case first - information, so that the last n pieces of information are always stored in the memory element M.

Precautions must of course be taken, including the shutdown all information contained in the storage element M of the manufacturing process clears. The deletion of all information from the storage organ crap also in necessary in those cases when an intervention is required due to the statistical regulation in the manufacturing process, even if this adjustment was made without a Shutdown of the manufacturing process was carried out. If that is before Information stored during this intervention remains in some storage units the results of the statistical control would be immediately after the procedure distorted and out of line with the new setting of the machine.

An example of a design based on the moving parameters continuously working statistical control device, which with code numbers r ' and S 'operates according to equations (11') and (12 ') is shown in FIG. 7 schematically shown.

From the machine PM - which in this example can be a centerless grinding machine - the products of a dimension to be detected - z. B. diameter - sorting device ST supplied, where they are sorted into three groups according to the predetermined control limits GL and CU: the oversized group (-I-), the dimensionally accurate group (g) and the undersized group (-). The counter C "sends an electrical pulse for each product, whereas the counters C,, and Cg send out pulses when a product belongs to the oversized or the dimensionally correct group.

The distribution device D distributes for each measured product the corresponding impulses, either "+" or "g", but in the case of undersized ones Do not produce a pulse to the corresponding storage unit. When classifying of the first product is the information to the storage unit Ml, for the second product to M., for the third product M3, etc. granted. The storage unit records whether the product in question in the group is "excessively true" or "true to size" belongs, and if the product is in the "undersized" or "minus" group, the storage unit does not receive a pulse and remains empty.

Claims (14)

Claims: 1. A method for statistical quality control of products of mass production and for regulating mass production, in which a predetermined number of copies of the produced products pass through a measuring device and the values determined by this are fed to a statistical evaluation device which generates control signals, characterized that the measuring range of the measuring device (Ga) is divided into separate areas by setting predetermined limit values (CL, CU) within the tolerances (TL, TU) , that in each area of the measuring device one of the numbers (z-, g, z of passing through this area copies corresponding number is generated by counting pulses +), that these pulses are fed to the statistical evaluation device (SE), that these be added in the device (SE), and that sums and / or differences of the field pulse numbers (z, g , z ,.) formed and with set control values values are compared and that this comparison is used to control the production. 2. The method according to claim 1, characterized in that that in the measuring range of the measuring device (GA) by setting two predetermined Limits is divided into three measuring ranges. 3. The method according to claim 2, characterized characterized in that in the static evaluation device (SE) the difference between the two external Area pulse numbers (z .. -z_) is formed. 4. The method according to claim 2, characterized characterized that in the statistical evaluation device the sum of twice the number of the one measuring area (2,) and the middle measuring area (g) is formed. 5. Procedure according to claim 2, characterized in that in the statistical evaluation device (SE) the sum of the counting pulses in the two external measuring ranges (z, J- z-) is formed. 6. The method according to claim 2, characterized in that im statistical evaluation device simultaneously the sums and differences of the counting pulses of the external measuring ranges are formed. 7. The method according to claim 2, characterized in that in the device (SE) at the same time the sum (g) of the pulses of the central measuring range and twice the sum of an external measuring range (2z +) are formed. B. Device for carrying out the method of statistical Quality control according to Claims 1 to 7, in which a measuring device is provided which corresponding to the measurement of undersized, dimensionally accurate or oversized Supplies corresponding impulses to a statistical evaluation device, thereby characterized that the statistical evaluation device (SE) according to the principle of the group method works and evaluates it on the basis of one or more statistical parameters. 9. Apparatus according to claim 8, characterized in that different summers are provided for the statistical evaluation device (SE), of which the first (C ") the number (n) of measurements, the second (CZ +) the number of the upper control limit (Cu) exceeding measured values (z +), the third (C, -) the number of the measured values (z_) falling below the lower control limit (CL ), the fourth (CS) the sum (S) of the values of the second (C ") and of the third (C, -) and the fifth (C,) determines the difference (r) between the values of the second (CZ +) and the third (C, -). 10. The device according to claim 8, characterized in that the evaluation device (SE) contains n storage units in which the pulses corresponding to each measurement are recorded one after the other in such a way that when a test object with a quality mark below the lower control limit (CL) was measured , the unit does not register a value if a test object with a quality mark is measured within the control limits (CL, Cu), the unit in question registers a value of ones and if a test object with a quality mark exceeding the upper control limit (Cu) is measured, the unit das Doubles of the ones value are registered and the evaluation unit forms a sum of all ones values in all (n) storage units and sends out a signal. 11. Device according to Claim 10, characterized in that the from several (n) storage units existing memory organ (M) is connected to a distributor (D), which the impulses corresponding to the quality mark from a sorting or measuring unit receives and distributes the same in the individual storage units, and further on a quenching unit (F), which is also operated by the distributor via a switch (S) and with their help the information that is stored in the individual storage units have been saved, are successively deleted. 12. The device according to claim 11, characterized in that each memory unit contains two actuating relays (R + and Rg) and a clearing relay (Rf) that the actuating relays (R +, R,), which indicate the occurrence of an "excessive" or "good" DUT by activating a double or single electrical unit, e.g. B. register the switching on in the evaluation circuit (s) of one of the resistors (2Ra or Ra), be fed with the relevant pulses (-f-) or (g) and one contact closes during the generation of the relay (C +2) or (C, 1) , which keeps the electrical voltage of a source (e.g. battery B) connected to the relevant relay until the extinguishing relay (R1) interrupts the relevant circuit, and that in the Circuit of the contact (Cg 1) holding the second relay (R,), another contact (C + 1), which opens due to the excitation of the first relay (R +), is switched on, through which only one of the two actuating relays (R. + or Rg) is permanently energized, whereby a combination of the impulses (-f-) or (g) only activates the first relay (R +). 13. Apparatus according to claim 12, characterized marked that the actuating relays (R;., Rg) each with two contacts (C + 4, C + 5 or C94, Cg5), of which the former (C + 4 and C14) are provided during arousal of the relevant relay opening contacts in a the occurrence of an undersized Test specimen indicating voltage line (v) are switched on, whereas the second Contact (C + 5) of the first relay (R +), which is activated when this relay (R +) closes, in a tensioning line indicating the occurrence of an oversized test object (t) and the second closing contact (C, 5) of the relay (R,) in a voltage line (U) is switched on, which indicates that the quality mark of the test item in question is in the control area. 14. The device according to claim 13, characterized in that the voltage lines (t, u, v) from all storage units (M1, M2 ... MN) are connected via a selector arrangement to a comparator in which the statistical control limits for the relevant characteristic values are set and the statistical passwords are compared with their limit values, and that the comparison element consists of two selectors (X, Y), each of which comprises two rows of contacts and a row of contacts of one selector can be switched through to a row of contacts of the second selector, that each contact of the first row is connected to a specific contact of the other row, and that the difference in the ordinal numbers of the contacts of the relevant rows for the given control plan corresponds to the control limit of the characteristic values to be compared. Documents considered: German Patent Specifications No. 1162 585; 583,724; USA: Patent Nos. 2,688,458, 2,688,740, 2767914.